SE531326C2 - Vertical shaft wind turbine - Google Patents

Description

30 531 325 2 In the case of a vertical shaft wind turbine, the turbine shaft is exposed to great stresses, partly due to the torque to be transmitted from the turbine to the generator and the influence of bending forces. This places great demands on the shaft's design and dimensioning, which entails high costs. in order to keep these costs at a reasonable level, one can of course be at the limits of the dimensioning. However, this entails a risk of operational disturbances and may mean that you are forced to set an upper limit for the wind pressure at which the unit must be stopped.

In addition, the bending forces are transmitted down to the wind power unit's generator, which leads to great demands on storage of the generator's rotor and / or risk of tilting of the generator shaft with accompanying operational disturbances.

The present invention has for its object to overcome the problems which are related to the mentioned types of stresses and thereby to provide a turbine shaft which becomes cheaper to manufacture but which nevertheless allows safe operation at high wind forces.

Disclosure of the invention The stated object is achieved according to the invention in that the upper shaft part is mounted in at least two row bearing bearings located at a distance from each other.

Thanks to this dichotomy through the joint, only the upper part of the shaft will be subjected to bending forces to the full extent. The lower part of the shaft can thus be dimensioned with lower requirements from this point of view and thus be made cheaper. In addition, the wind turbine becomes more reliable in that the bending forces only fully act on the upper shaft part and thus to a reduced extent reach down towards the turbine shaft's connection to the wind power unit's generator.

By such a bearing of the upper shaft part, a stable absorption of bending forces is achieved so that the position of the joint is fixed. This further contributes to reducing the impact of bending forces on the lower shaft portion.

According to a preferred embodiment, the upper shaft part is shorter than the lower shaft part. 20 25 30 ET! 325 3 Thus, the part of the turbine shaft which is subjected to bending forces to a reduced degree will be large, which means that the advantages of the articulated arrangement will be relatively tangible.

It is preferred that the length of the lower shaft part is 5 to 20 times as long as the length of the lower shaft part.

This is in most cases the optimal balancing of the relative lengths of the shaft parts, taking into account on the one hand the advantages of making the lower shaft part as long as possible and on the other hand having a sufficient length of the upper shaft part to enable a stable storage of the same.

According to a further preferred embodiment, the upper shaft part and the lower shaft part have different construction, where the upper shaft part is designed to be able to absorb both torque and bending moment while the lower shaft part is designed to be able to absorb torque and to a lesser extent than the upper shaft part record bending moments.

This fully utilizes the possibility of achieving a cheaper turbine shaft.

According to a further preferred embodiment, the lower shaft part is connected via a second link to a generator shaft.

This further reduces the risk of bending stresses being transmitted to the generator shaft. This thus becomes even more reliable and storage can be made easier.

The invention also relates to a wind power unit provided with a wind turbine according to the invention or one of the preferred embodiments thereof.

Furthermore, according to the invention, an electrical network is connected to a wind power unit according to the invention.

According to the invented use, the wind turbine is used to generate electrical energy.

The invented wind turbine, the invented electrical network and the invented method entail corresponding advantages as stated above for the invented wind turbine and the preferred embodiments thereof.

The invention is explained in more detail by the following detailed description of an advantageous embodiment thereof. 530 325 Brief description of figure Fig. 1 is a vertical section through a wind power unit provided with a wind turbine according to the invention.

Description of advantageous embodiment I fi g. 1 illustrates a wind turbine according to the invention arranged in a wind power unit which in addition to the wind turbine comprises a foundation 1 and a support pillar 2 which rests on the foundation 1 and is anchored thereto with anchoring devices 5. Furthermore, a generator 6 is included.

The wind turbine has a vertical shaft 3 and a rotor with vertical turbine blades 4.

Each turbine blade 4 is connected to the turbine shaft by two support arms 9. The wind turbine shown has a so-called H-rotor, but the invention is of course applicable to other types of vertical shaft wind turbines.

The turbine shaft 3 consists of an upper shaft part 10 and a lower shaft part 11.

These two are connected by a joint 13 which allows torque transmission.

The joint 13 is suitably a universal joint, for example a ball joint or a universal joint.

The upper shaft part 10 is considerably shorter than the lower shaft part 11.

For a total length of the turbine shaft 3 of 40 meters, the length of the upper shaft part 10 is suitably in the order of 5-6 m.

The upper shaft part 10 is mounted in two radial bearings 15, 16 where the upper radial bearing 15 is arranged at the upper end of the support column 2 and the lower radial bearing at the lower end of the upper shaft part 10 next to the joint 13. Furthermore an axial bearing 17 is arranged to receive the whole or parts of the weight of the wind turbine.

The lower shaft part 11 is preferably but not necessarily radially mounted. The example illustrated in the figure is provided with an upper radial bearing 18 and a lower radial bearing 19. An axial bearing 20 can also be provided for the lower shaft part 11.

The lower shaft part 11 is connected to the generator shaft 12. This can be designed as a rigid joint or in that the generator shaft 12 forms a direct extension of the lower shaft part 11. It may be advantageous, however, as shown in the figure, to also design this joint as a universal joint 14 .

Both the upper shaft part 10 and the lower shaft part 11 are suitably hollow. The lower shaft part 11 is made with a thinner wall than the upper shaft part 11 because it needs to absorb bending moments to a lesser extent. The outer diameter of the respective shaft can also be different for the upper shaft part and the lower shaft part. In the example shown, the lower shaft part 11 has a slightly larger outer diameter.

Claims (11)

20 25 30 531 325 å ..- PATE NTKRAV Wind turbine with a vertical turbine shaft (3), which turbine shaft (3) is provided with a joint (13) so that the turbine shaft (3) consists of an upper shaft part (10) and a lower shaft part (11), characterized in that the upper shaft part (10) is mounted in at least two radial bearings (15, 16) spaced apart. Wind turbine according to Claim 1, characterized in that the upper shaft part (10) is shorter than the lower shaft part (11). Wind turbine according to Claim 2, characterized in that the length of the lower shaft part (11) is 5 to 20 times as long as the length of the upper shaft part (10). Wind turbine according to one of Claims 1 to 3, characterized in that the upper shaft part (10) and the lower shaft part (11) have different constructions, the upper shaft part (10) being designed to be able to absorb both torque and bending while the lower the shaft part (11) is designed to be able to absorb torque substantially and to be able to absorb bending torque to a lesser extent than the upper shaft part. Wind turbine according to one of Claims 1 to 4, characterized in that the lower shaft part is connected to a generator shaft (12) via a second link (1Ä). Wind power unit, characterized in that it is equipped with a wind turbine according to one of claims 1 to 5. Wind power unit according to claim 6, characterized in that the generator is a synchronous generator. Wind power unit according to Claim 6 or 7, characterized in that the generator is permanently magnetized. 531 325 v-íí Wind power unit according to one of Claims 6 to 8, characterized in that the generator is connected to an AC or DC network. Wind power unit according to claim 9, characterized in that the generator is connected to a 50 or 60 Hz network via a DC intermediate. . Use of a wind turbine according to any one of claims 1 to 6 for generating electrical energy.